Operating a touch screen control system according to a plurality of rule sets

ABSTRACT

A touch screen control system communicates with a host processing system (HPS). The touch screen control system includes a memory and control circuitry. The control circuitry operates a touch screen according to rules stored in the memory by: during a first time period and in response to detecting a first type of user input with a touch sensor of the touch screen, updating a display screen of the touch screen autonomously without requiring intervention from the HPS following the detection of the first type of user input; during the first time period and in response to detecting a second type of user input with the touch sensor, updating the display screen according to directions provided by the HPS; and during a second time period and in response to detecting the first type of user input with the touch sensor, updating the display screen according to directions provided by the HPS.

CROSS-REFERENCE TO RELATED U.S. APPLICATIONS Continuation

This application is a continuation application of and claims the benefitof co-pending U.S. patent application Ser. No. 14/050,191 filed on Oct.9, 2013, entitled “OPERATING A TOUCH SCREEN CONTROL SYSTEM ACCORDING TOA PLURALITY OF RULE SETS,” by Shawn P. Day et al., having AttorneyDocket No. SYNA-20090423-D1B.CON, assigned to the assignee of thepresent application, and hereby incorporated by reference herein in itsentirety.

U.S. patent application Ser. No. 14/050,191 was a continuationapplication of and claimed the benefit of U.S. patent application Ser.No. 12/770,619, filed on Apr. 29, 2010, entitled “OPERATING A TOUCHSCREEN CONTROL SYSTEM ACCORDING TO A PLURALITY OF RULE SETS,” by ShawnP. Day et al., having Attorney Docket No. SYNA-20090423-D1B, andassigned to the assignee of the present application; U.S. patentapplication Ser. No. 12/770,619 was incorporated by reference in itsentirety into U.S. patent application Ser. No. 14/050,191.

U.S. patent application Ser. No. 12/770,619 claimed priority to andbenefit of U.S. Provisional Application 61/174,403 filed Apr. 30, 2009,entitled “REDUCING LATENCY ASSOCIATED WITH INTERACTIONS WITH A TOUCHSCREEN DEVICE,” by Shawn P. Day et al.; and also incorporatedprovisional application 61/174,403 by reference in its entirety

BACKGROUND

Electronic devices are ubiquitous in today's society. As the technologyof electronic devices advances, the number of integrated functionsenabled on such devices also increases. As an example, many of today'selectronic devices include the ability to display information to usersand to receive touch based input from users. In order to receive andprocess touch based input, many current electronic devices utilizecapacitive sensing devices in combination with display devices.Typically such capacitive sensing devices process user input receivedfrom, for example, one or more fingers, styli, or other object in asensing region of the capacitive sensor device.

However, as the number of integrated functions increases on electronicdevices, the processing burdens imposed on their host processors alsoincrease. (As an example, when an electronic device includes both adisplay and a capacitive sensor device, the host processor of theelectronic device handles processing for both components.) As a result,the electronic devices may suffer from performance shortcomings due tothe burden placed on their host processors. For example, a delay betweenuser input and visual feedback to the user may arise because of hostprocessor-induced latency.

As a result of such shortcomings, users may become frustrated and/orconfused. User frustration or confusion may lead to user dissatisfactionor cause the users to perform repetitive and/or unnecessary user inputactions which further burden the host processors. Additionally, as thenumber of the functions integrated onto electronic devices increases,power consumption also increases.

Taking mobile devices as a specific example, the use of mobile devicesoften require loading, displaying and controlling large amounts of dataincluding pictures, web pages, maps, text and non-textual documents,etc. In some mobile devices, there is often a delay between user input(e.g. taps, double-taps, scroll commands, etc.) and visual feedback tothe user.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example of an electronic device, in accordancewith an embodiment of the present invention.

FIG. 2 illustrates an example of a touch screen control system, inaccordance with an embodiment of the present invention.

FIG. 3 illustrates another example of a touch screen control system, inaccordance with an embodiment of the present invention.

FIG. 4 illustrates an example method for operating a touch screencontrol system, in accordance with an embodiment of the presentinvention.

FIGS. 5A-7B illustrates examples of visual feedback provided in responseto user input, in accordance with embodiments of the present invention.

The drawings referred to in this description should be understood as notbeing drawn to scale except if specifically noted.

DESCRIPTION OF EMBODIMENTS

Reference will now be made in detail to embodiments of the presentinvention, examples of which are illustrated in the accompanyingdrawings. While the invention will be described in conjunction withvarious embodiment(s), it will be understood that the descriptions arenot intended to limit the present invention to these embodiments. On thecontrary, the present invention is intended to cover alternatives,modifications and equivalents, which may be included within the spiritand scope of the various embodiments as defined by the appended claims.

Furthermore, in the following description of embodiments, numerousspecific details are set forth in order to provide a thoroughunderstanding of the present invention. However, the present inventionmay be practiced with a subset or without these specific details. Inother cases, well known methods, procedures, components, and circuitshave not been described in detail as not to unnecessarily obscureaspects of the present embodiments.

Description of Components

FIG. 1 depicts electronic device 100, in accordance with an embodimentof the present invention. Electronic device 100 includes touch screencontrol system (TSCS) 110 (which includes control circuitry 112 andmemory 114). Connecting arrows 170, 180, and 190 indicate that, in someembodiments, host processing system 160 has bidirectional interactionswith TSCS 110, TSCS 110 has bidirectional interactions with touch sensor150, and TSCS 110 has bidirectional interactions with display screen140. In other embodiments, some or all of these interactions may beunidirectional.

In various embodiments, electronic device 100 is any electronic devicethat comprises the aforementioned components and functions (e.g.,receives user input and updates a display screen). For example,electronic device 100 may comprise: personal computers (e.g. desktopcomputers, laptop computers, portable computers, workstations, personaldigital assistants, and video game machines), communication devices(e.g. wireless phones, pagers, and other messaging devices), mediadevices that record and/or play various forms of media (e.g.televisions, cable boxes, music players, digital picture frames, videoplayers, digital cameras, and video cameras), peripherals to largersystems (e.g. printers, keyboards, and remote controls), white goods(e.g. appliances), automotive devices, industrial devices, electronictoys, and any other electrical device that could benefit from having asophisticated user interface that does not significantly burden its hostprocessing system.

In some embodiments, elements of electronic device 100 are physicallyunified, and TSCS 110, display screen 140, touch sensor 150, and hostprocessing system 160 are all disposed within a common housing. Forexample, electronic device 100 may be a handheld computing system.

Display screen 140 is configured for displaying images. Display screen140 may be a cathode ray tube (CRT), a liquid crystal display (LCD), anorganic light emitting diode (OLED) display, an electroluminescentdisplay, or any other type of display screen suitable to be integratedin an electronic device. Additionally, in some embodiments, electronicdevice 100 includes a backlight (not shown) to enhance visibility ofimages on display screen 140.

Touch sensor 150 is shown in FIG. 1 as a dotted rectangle overlappingdisplay screen 140. However, in various embodiments, the actual physicalsensor components of touch sensor 150 may be located inside or outsideof the dotted rectangle.

Although called a “touch” sensor, embodiments of touch sensor 150 mayrespond to contact or non-contact user input in their respective sensingregions. The sensing region overlaps with an active area of displayscreen 140. The active area is the region in which electronic images maybe displayed by display screen 140. It will be understood that someembodiments of display screen 140 may include regions, such as borderregions, in which electronic images may not be displayed.

Embodiments of touch sensor 150 may demark their sensing regions usingsurfaces. During operation, touch sensor 150 is operated to detect oneor more input objects in the sensing region, for sensing user input.“Sensing region” as used herein is intended to broadly encompass anyspace where touch sensor 150 is able to reliably detect an input object.In some embodiments of touch sensor 150, the sensing region extends froma surface of touch sensor 150 in one or more directions into space untildecreased signal-to-noise prevents accurate object detection. Thisdistance may be on the order of less than a millimeter, millimeters,centimeters, or more, and may vary significantly with the type ofsensing technology used and the accuracy desired. Thus, embodiments mayrequire contact with the surface, either with or without appliedpressure, while others do not. Accordingly, in some embodiments, theplanarity, size, shape and exact locations of the particular sensingregions vary widely from embodiment to embodiment.

Touch sensor 150 may utilize any combination of sensor components andsensing technologies. As several non-limiting examples, touch sensor 150may use capacitive, elastive, resistive, inductive, surface acousticwave, optical, or other techniques. Data gathered by touch sensor 150may be used to determine the presence, location and/or motion of one ormore fingers, styli, and/or other objects.

In some resistive implementations of touch sensor 150, a flexible andconductive first layer is separated by one or more spacer elements froma conductive second layer. During operation, one or more voltagegradients are created across the layers. Pressing the flexible firstlayer may deflect it sufficiently to create electrical contact betweenthe layers, resulting in voltage outputs reflective of the point(s) ofcontact between the layers. These voltage outputs may be used todetermine positional information.

In some inductive implementations of touch sensor 150, one or moresensor elements pick up loop currents induced by a resonating coil orpair of coils. Some combination of the magnitude, phase, and frequencyto determine positional information.

In some capacitive implementations of touch sensor 150, voltage orcurrent is applied to create an electric field. Nearby input objectscaused changes in capacitive coupling that may detect be detected aschanges in voltage, current, or the like.

Some capacitive implementations utilize arrays or other patterns ofcapacitive sensor electrodes to create electric fields. Some capacitiveimplementations utilize resistive sheets, which may be uniformlyresistive.

Some capacitive implementations utilize “self capacitance” (also“absolute capacitance”) sensing methods based on the capacitive couplingbetween sensor electrodes and free space. In one implementation, anabsolute capacitance sensing method operates by modulating sensorelectrodes with respect to a reference voltage (e.g. system ground), andby detecting the capacitive coupling between sensor electrodes and inputobjects.

Some capacitive implementations utilize “mutual capacitance” (also“transcapacitance”) sensing methods based on the capacitive couplingbetween sensor electrodes. In one implementation, a transcapacitivesensing method operates by detecting the capacitive coupling between oneor more transmitting electrodes and one or more receiving electrodes.Transmitting sensor electrodes may be substantially modulated relativeto a reference voltage (e.g. system ground) to facilitate transmission,and receiving sensor electrodes may be held substantially constantrelative to the reference voltage to facilitate receipt. Sensorelectrodes may be dedicated transmitters or receivers, or transmit aswell as receive.

Host processing system 160 may be utilized for processing images fordisplay on display screen 140. For example, to display video on displayscreen 140 in some embodiments, host processing system 160 providesimage data for the video frames, such that display screen 140 maypresent the video to users.

In some embodiments, host processing system 160 is configured forprimary processing of the images for display on display screen 140. Thatis, host processing system 160 is configured to perform a majority ofthe processing of images for display on display screen 140. In otherwords, in some embodiments, electronic device 100 is designed such thata majority of image data to be display on display screen 140 would passthrough and be processed by host processing system 160. However, in someembodiments, host processing system 160 is not configured for primaryprocessing of the images for display on display screen 140, and hostprocessing system 160 does little or no processing of the images fordisplay on display screen 140.

A “primary image” is an image processed by a host processing system andheld in a memory of a touch screen control system TSCS 110 (e.g. amemory that may be separate from or be part or memory 114) for primarydisplay on display screen 140. The primary image may be static or maychange over a period of time. In some embodiments, the primary image ismodified, or replaced entirely by host processing system 160, by TSCS110, or by both.

An image is “updated” in memory when the data representing the image ischanged in part or in whole. In some embodiments, host processing system150 or TSCS 110 (e.g. using control circuitry 112) changes bitsassociated with the changed portion(s), or writes new image data toreplace what is stored in the memory.

An image is “updated” on display screen 140 when the display of theimage by display screen 140 is changed in part or in whole. In someembodiments, TSCS 110 (e.g. using control circuitry 112) changes one ormore portions of an image displayed on display screen 140, or replacesthe image displayed on display screen 140 entirely.

“Display image update rate” as used herein generally indicates the rateat which the image on display screen 140 is updated. For example, sometypical display image update rates associated with animation or video ofreasonable quality include 15, 24, and 30 frames per second. As anotherexample, a typical display image update rate associated with qualityuser interface experience is 60 frames per second.

“Image data update rate” as used herein generally indicates the rate atwhich image data is updated in a memory of TSCS 110 (e.g. first memory131 described below). The updating of image data in the memory of TSCS110 may be by host processing system 160, TSCS 110, or some otherelement.

In various embodiments, in accordance with the present invention, TSCS110 operates touch sensor 150 to detect user input in the sensing regionand operates display screen 140 to display images in response to theuser input, without requiring intervention by host processor 160. Inother words TSCS 110 autonomously operate touch sensor 150 and displayscreen 140, without real-time host image processing performed ordirection provided directly in response to the user input in the sensingregion. TSCS 110 may perform these functions according to hardwiredrules or with rules previously provided by host processing system 160.

In some embodiments, host processing system 160 is in sometimes alow-power state (including potentially being off) while TSCS 110 isoperating autonomously. In some embodiments, host processing system 160sometimes performs processing or provides instructions not directlyrelated to updating display screen 140 or not directly in response tothe user input.

In embodiments of electronic device 100, such autonomous operation byTSCS 110 reduces or eliminates the shortcomings as describe above. Forexample, such autonomous operation may reduce latency, reduce responsetime variability, and increase responsiveness to user input. Theseimprovements can increase a user's sense of ease, comfort, or confidencein the operation of electronic device 100.

In embodiments of electronic device 100, such autonomous operationreduces the processing required of host processing system 160, and thuscan reduce power consumption by electronic device 100. For example, hostprocessing system 160 may enter a low power state while the updating ofimages on display screen 140 is done locally by TSCS 110. Examples oflow power states include off states, sleep states, and states where hostprocessing system 160 expends less processing power.

In addition, in embodiments of electronic device 100, such autonomousoperation reduces the maximum image data update rate that hostprocessing system 160 needs to support while still providing smooth andresponsive feedback. For example, TSCS 110 may be configured such thatit can produce images and update display screen 140 at a higher ratethan host processing system 160 can update the primary image held in amemory of TSCS 110 (e.g. memory 114). In some embodiments, TSCS 110 isable to produce updated displays at 60 Hz or higher in response to userinput. This offloads host processing system 160 such that hostprocessing system 160 may be configured with a maximum update rate lowerthan 60 Hz (e.g., 30 Hz) without significant detrimental impact on userexperience. This also allows electronic device 100 to have relaxedrequirements for communications bandwidth (e.g., serial linkrequirements), other performance characteristics, and the like. Therelaxed requirements may provide greater design choice and cost savings.

Some embodiments of electronic device 100 are able to update displayscreen 140 faster than host processing system 160 can update the primaryimage. That is, some embodiments of electronic device 100 support adisplay image update rate greater than the image data update rateassociated with host processing system 160. For example, in someembodiments, TSCS 110 is configured to be able to generate updatedimages and update display screen 140 at a faster rate than if hostprocessing system 160 performed the image processing. This TSCS 110functionality supports the greater display image update rate in thosesystems.

Regardless of the maximum update rates, in operation, the image dataupdate rate utilized may be significantly lower than display screen 140update rate utilized. For example, TSCS 110 may blend images to providevisual feedback during a function such as a drag function (blending isdiscussed in further detail below). The primary image may be the“background” over which the item dragged moves, and image data held inmemory for the primary image may change infrequently or not at allduring the drag function. Thus, a lower image data update rate isutilized (compared to the display image update rate used) by someembodiments.

The image of the item dragged may stay static in memory during the dragfunction. However, the blending coordinates associated with the image ofthe item dragged may change during the drag function. TSCS 110 updatesdisplay screen 140 with autonomously generated images blending the imageof the item dragged at locations specified by the blending coordinates,effectively moving the dragged item relative to the primary image ordisplay screen 140, or both. Thus, a higher display image update rate isutilized (compared to the image data update rate used).

In various embodiments, TSCS 110 operates touch sensor 150 to obtainmeasurements that enable the determination of user input characteristicssuch as number and motion of input objects. Such measurement(s) areutilized by TSCS 110, in some embodiments, to determine positionalinformation with respect to a user input relative to the sensing regionof touch sensor 150.

The term “positional information” as used herein is intended to broadlyencompass absolute and relative position-type information, includingmotion in one or more directions and also other types of spatial-domaininformation such as velocity, acceleration, and the like. Various formsof positional information may also include time history components, asin the case of gesture recognition and the like. The positionalinformation from TSCS 110 may be used for facilitating a full range ofinterface actions, including use of the proximity sensor device as apointing device for cursor control, scrolling, and other functions.

Elements of TSCS 110 may be implemented as part or all of one or moreintegrated circuits and/or discrete components physically separate fromhost processing system 160. That is, TSCS 110 may comprise part or allof one IC that is separate from host processing system 160. Similarly,TSCS 110 may comprise parts or all of multiple ICs that are separatefrom host processing system 160.

Embodiments of TSCS 110 may include computational capability thatenables it to discriminate or ascertain proper responses to user input.For example, TSCS 110 may make decisions, formulate responses, or causeactions by itself. Also, TSCS 110 may respond to user input that arerelevant to one or more electronic applications, without requiringconstant or periodic communications with host processing system 160.Example responses include adjustments to an image being displayed.

In various embodiments, TSCS 110 comprises logic circuitry. The logiccircuitry is configured to control the flow of information with hostprocessing system 160. For example, the logic circuitry can control theflow of communication between host processing system 160 and TSCS 110.As another example, the logic circuitry can provide discriminatory orinterpretive capabilities in the communications. With suchconfigurations, the logic circuitry can reduce the frequency ofinteractions needed with host processing system 160 for operatingdisplay screen 140 and touch sensor 150.

The logic circuitry may comprise circuitry specifically for implementingthe computational logic, general use processor circuitry programmed toperform the functions of the computational logic, or a combinationthereof. For example, in some embodiments, the logic circuitry is hardwired with rules. As another example, in some embodiments, the logiccircuitry comprises computational circuitry coupled with appropriaterules held in memory. The rules may comprise computer-executable code,data associating actions with conditions stored in tables or otherstructures, etc.

The logic implemented can be application specific. In some embodiments,this is enabled by employing different logic circuits in conjunctionwith different applications. In some embodiments, this is enabled byemploying different rule sets held simultaneously in memory. In somefurther embodiments, this is enabled by loading new rules into memory.

FIG. 2 depicts a TSCS 110 that can be coupled with host processingsystem 160 (shown in FIG. 1), in accordance with an embodiment of thepresent invention. TSCS 110 includes TSCC (touch screen controlcircuitry) 120 for operating touch sensor 150, DCC (display controlcircuitry) 130 for operating display screen 140, and memory 114 forstoring rules of operation.

As discussed above, elements of TSCS 110 may be implemented as part orall of one or more integrated circuits and/or discrete componentsphysically separate from host processing system 160. Thus, embodimentsof TSCS 110 in accordance to the present invention are well suited tohaving discrete components, such as ICs that each solely comprises aTSCC 120 or DCC 130, and the like. Embodiments of TSCS 110 in accordanceto the present invention are also well suited to being integrated in asingle IC, such as one IC that forms parts or all of TSCC 120 and DCC130.

In some embodiments, TSCC 120 and DCC 130 do not share circuitry. Thatis, circuitry used to operate the touch sensor 150 is not used tooperate display screen 140, and vice versa. In some embodiments, TSCC120 and DCC 130 of control circuitry 112 do share circuitry, such thatcircuitry of TSCC 120 is also circuitry of DCC 130. For example,circuitry specific to operation of touch sensor 150 and circuitryspecific to operation of display screen 140 may be physically coupled toa same processing unit that performs computations for both touch sensorand display operation. As another example, TSCC 120 and DCC 130 ofcontrol circuitry 112 may hold data in the same memory.

Some embodiments of the present invention provide direct communicationbetween TSCC 120 and DCC 130. In some embodiments, this directcommunication is enabled by one or more communication channels couplingdiscrete ICs comprising TSCC 120 and DCC 130. In some embodiments, thisdirect communication is enabled by integrating at least parts of TSCC120 and DCC 130 in one IC. This direct communication reduce the dutiesof host processing system 160 associated with performing some touch ordisplay tasks. TSCC 120 may send information such as touch coordinatesor gesture commands to DCC 130 before or in parallel with sending themto host processing system 160.

In some embodiments, memory 114 is physically distinct from hostprocessing system 160.

FIG. 3 illustrates another example of TSCS 110, in accordance with anembodiment of the present invention, which may be coupled with hostprocessing system 160 (shown in FIG. 1). As shown in FIG. 3, in someembodiments, TSCS 110 optionally includes a first memory 131 and asecond memory 132, for storing images for display on display screen 140.In some embodiments of TSCS 110 comprising first and second memories 131and 132, at least part of first and second memories 131 and 132 (e.g.part or all of one or both first memory 131 and second memory 132) arepart of memory 114. However, in some other embodiments comprising firstand second memories 131 and 132, at least part of first and secondmemories 131 and 132 are physically separate from memory 114. Also,first memory 131 and second memory 132 may be disposed as physicallyseparate memory structures or be partitions of the same memorystructure.

In some embodiments, second memory 132 is smaller in memory capacitythan first memory 131. And, in some embodiments, first memory 131 is aframe buffer.

Also, as shown in FIG. 3, in some embodiments, DCC 130 optionallyincludes display refresh circuitry 134 for refreshing display screen 140with images. Display refresh circuitry optionally includes displayscreen updater 136 for updating display screen 140 and blended imagegenerator 138 for generating blended images using images stored in firstmemory 131 and second memory 132. Further, in some embodiments, TSCS 110optionally includes a device control module 125 for controlling othermodules.

In various embodiments, one or more of these components of TSCS 110share circuitry with each other, and/or with another part of TSCS 110.These components, along with other parts of TSCS 110 may be implementedas part or all of one or more integrated circuits and/or discretecomponents.

Description of Components in Operation

FIG. 4 depicts a method for operating electronic system 100 and TSCS 110of FIG. 1 in accordance with an embodiment of the present invention. Themethod shown in FIG. 4 will be described in conjunction with FIGS.5A-7B. In one embodiment, method 400 is carried out by processors andelectrical components operating according to computer-readable andcomputer-executable code. The computer-readable and computer-executablecode may reside, for example, in a data storage medium such ascomputer-usable volatile and non-volatile memory. However, thecomputer-readable and computer-executable code may reside in any type ofcomputer-readable storage medium. In some embodiments, method 400 isperformed at least by the system(s) described in FIGS. 1-3 and 5A-7B. Inparticular, FIGS. 5A-7B depict various embodiments of displaying imageson display screen 140.

In the embodiments discussed below, control circuitry 112 is describedas performing most of the operation associated with operating touchsensor 150, updating display screen 140, and communicating with hostprocessing system 160. It is understood that, in some embodiments, otherparts of TSCS 110 may perform some or all of these functions.

At 410 of method 400, display screen 140 is updated by control circuitry112 in response to image data received from host processing system 160.For example, in one embodiment, in reference to FIG. 5A, display screen140 is updated in response to image data from host processing system160. Images received from host processing system 160 can comprise videoframes, pictures, web pages, maps, textual and non-textual documents,etc.

At 420 of method 400, a first set of rules is held in memory 114 of TSCS110. In general, sets of rules direct control circuitry 112 to operatein a certain manner. In various embodiments, control circuitry 112 canoperate under any number of rules (e.g., a first set of rules, a secondset of rules, etc.). For example, one set of rules may direct controlcircuitry 112 to operate in a certain manner in response to one kind ofuser input (e.g., a double tap in a predefined portion of the sensingregion). Likewise, another set of rules may direct control circuitry 112to operate in a different manner in response to the same kind or anotherkind of user input (e.g., a double tap in the same predefined portion ofthe sensing region, or a double tap in a different predefined portion ofthe sensing region).

In one embodiment, memory 114 is configured to hold a plurality of setsof rules (e.g., a first set of rules and a second set of rules)simultaneously. It should be appreciated that any number of rules orrule sets can be held simultaneously. For example, in some embodiments,the sets of rules are loaded at manufacture and held simultaneously. Asanother example, in various embodiments, the sets of rules are loaded byhost processing system 160 at start-up, when coming out of hibernation,when waking up, when unlocking, and/or the like. As a further example,in some embodiments, the sets of rules are loaded by host processingsystem 160 in response to particular applications running or particularfunctions initiating. As yet another example, some embodiments use acombination of the above, (e.g., some rules are loaded at manufacture orat start-up, and others are loaded dynamically during operation ofelectronic device 100).

In some embodiments where memory 114 is configured to hold multiple rulesets, pointers or other indicators denote the active set of rules. Insome embodiments where memory 114 is configured to hold multiple rulesets, a most recently loaded rule set is the active set of rules.

In another embodiment, memory 114 is configured to hold different setsof rules (e.g., a first set of rules and a second set of rules) atdifferent times. In some embodiments, the set of rules held at anyparticular time is the active rule set. For example, a first set ofrules can be loaded into memory 114 by host processing system 160 at afirst time and be replaced by a second set of rules at a later time. Thefirst time or the later time may be associated with shutting down orstarting up, going to sleep or waking up, hibernating or coming out ofhibernation, being locked or unlocked, particular applications running,particular applications having priority or focus, particular imagesbeing shown, particular operation status, a particular user logged in,etc.

In some embodiments, replacing the first set of rules with the secondset of rules is in response to receiving an indication from hostprocessing system 160, which is discussed in detail below. In oneembodiment, control circuitry 112 receives the indication from hostprocessing system 160 by receiving the second set of rules.

In some embodiments, control circuitry 112 operates touch sensor 150 todetect user input in the sensing region of touch sensor 150, whichoverlaps the active area of display screen 140. At 430 of method 400,user input is detected in the sensing region. For example, the userinput may comprise a variety of types of user input. For example, touchsensor 150 may comprise a contactable surface, and the user input maycomprise a contact with the surface meeting specific size or contactpatch area considerations. As another example, the user input maycomprise a non-contacting motion of a large input object in the sensingregion.

At 440 of method 400, control circuitry 112 operates according to thefirst set of rules. For example, a first set of rules may direct controlcircuitry 112 to operate in a certain manner in response to a first typeof user input.

At 450 of method 400, in response to receiving an indication from hostprocessing system 160, control circuitry 112 switches from operatingaccording to the first set of rules to operating according to a secondset of rules.

At 460 of method 400, control circuitry 112 operates according to thesecond set of rules. For example, the second set of rules may directcontrol circuitry 112 to operate in a different manner in response tothe first type of user input (different from the certain mannerprescribed by the first set of rules).

In some embodiments, at least one of the first set of rules and thesecond set of rules defines when control circuitry 112 updates displayscreen 140 in response to the user input detected in the sensing regionof touch sensor 150. “Defines when” is used here to mean “defines if”than “defines what time.” For example, in some embodiments, one or bothof the first and second sets of rules defines what type(s) of user inputtriggers an update to display screen 140. These sets of rules may or maynot impose any requirements about at what time updates to display screen140 are made.

Sets of rules may include rules from any appropriate space of potentialrules. For example, sets of rules may define when control circuitry 112autonomously updates display screen 140 in response to user input. Insome embodiments, some rule sets are configured to cause controlcircuitry 112 to never autonomously update display screen 140 inresponse to user input. For example, these sets of rules may haveexplicit rules for not autonomously updating, or merely have no rulesfor autonomously updating.

In some embodiments, some rule sets are configured to cause controlcircuitry 112 to sometimes autonomously update display screen 140 inresponse to user input, such as by causing control circuitry 112 toautonomously update display screen 140 when particular conditions aremet. For example, in some embodiments, some rule sets are configured tocause control circuitry to autonomously update display screen 140 inresponse to a first type of user input, and not in response to a secondtype of user input.

In some embodiments, some rule sets are configured to cause controlcircuitry 112 to always autonomously update display screen 140 inresponse to user input. For example, these sets of rules may haveexplicit rules for handling all types of user input, or merely have norules for non-autonomous updating of display screen 140 (e.g. inabilityto act on updates by host processing system 160).

The rule sets may also define how the display screen is updated. Forexample, sets of rules can also define which graphical elements areupdated, at what time the graphical elements are updated, and the like.For example, some rule sets may associate different images withdifferent user inputs, and define which image to display in response towhich user input. As another example, some rule sets may define whattime to display the image (e.g., display the image an amount of timeafter receiving the user input, display the image for a duration oftime, etc.). As yet another example, some rule sets may define othercharacteristics associated with the image (e.g. brightness, intensity,color, size, fade in/out, etc.)

Sets of rules may define when control circuitry 112 reports informationabout user input to host processing system 160. In some embodiments,some rule sets are configured to cause control circuitry 112 to neverreport information about the user input to host processing system 160.For example, these sets of rules may have explicit rules for notreporting, or merely have no rules for reporting.

In some embodiments, some rule sets are configured to cause controlcircuitry 112 to sometimes report information about the user input tohost processing system 160, such as by causing control circuitry 112 toreport information when particular conditions are met. For example, insome embodiments, some rule sets are configured to cause controlcircuitry 112 to report information in response to a first type of userinput, and not in response to a second type of user input.

In some embodiments, some rule sets are configured to cause controlcircuitry 112 to always report information about the user input to hostprocessing system 160. For example, these sets of rules may haveexplicit rules for always reporting, or merely have no rules for notreporting.

The rule sets may also define how the information about the user inputis reported. For example, some rule sets may associate different typesof signals (e.g. different bit sequences) with different user inputs,and define which signal to provide in response to which user input. Asanother example, some rule sets may define what time to provide theinformation (e.g., convey the information an amount of time afterreceiving the user input, report it once or repeat the report, etc.) Asyet another example, some rule sets may define other reportingcharacteristics.

For example, in some embodiments, some rule sets may include rules fromany one or combination of the following:

Regular Reporting: Rules of this type cause control circuitry 112 tomake regular reports of information about user input information to hostprocessing system 160. For example, the reporting may be triggered by atimer such that the reports are periodic. As other examples, thereporting may be triggered by counters or events unrelated to user inputin the sensing region of touch sensor 150.

Report Gesture Events: Rules of this type cause control circuitry 112 toreport instances of gestures to host processing system 160. Someembodiments of control circuitry 112 operating according to this type ofrule analyze the user input and recognize gestures, and provideindications of those gestures to host processing system 160. Forexample, control circuitry 112 may recognize that two input objects havecontacted a surface of touch sensor 150 for a short duration, and reportthe occurrence of a two-finger-tap to host processing system 160. Asanother example, control circuitry 112 may recognize that an inputobject is hovering over a location on a surface of touch sensor 150associated with turning on keyboard function, and report a keyboardactuation input to host processing system 160.

Some embodiments of control circuitry 112 operating according to these“report gesture events” types of rules analyze the user input todetermine that user input meeting particular criteria is received, andreport images of the user input to host processing system 160. Forexample, control circuitry 112 may recognize a contact by an inputobject to a surface of touch sensor 150 lasting a duration longer than areference duration, and send images of the contact to host processingsystem 160 for analysis by host processing system 160.

Report Selected Gestures: Rules of this type are configured to causecontrol circuitry 112 to report only some of a subset of gesturesrecognized by control circuitry 112. For example, some embodiments ofcontrol circuitry 112 operating according this type of rules report tapsthat occur within specific portions of the sensing region of touchsensor 150 that correspond to parts of a GUI interface shown on displayscreen 140, and not to report taps that occur in other portions of thesensing region. In some embodiments, the gestures areapplication-specific.

Report at Selected Parts of Input Sequences: Rules of this type areconfigured to cause control circuitry 112 to report only at particularparts of input sequences. For example, these rules may cause controlcircuitry 112 to report only at the start of an input sequence, the endof an input sequence, or at both the start and the end. Controlcircuitry 112 may operate to provide user feedback as appropriate,without intervention by host processing system 160. For example, aninput sequence comprising typing on a virtual keyboard may be reportedby control circuitry 112 when words or lines are completed (e.g. whenthe space bar or enter key is actuated), when a certain number ofcharacters have been inputted, and the like. As another example, aninput sequence tracing out a character or word may be reported bycontrol circuitry 112 when the tracing appears complete (e.g., after acertain number of strokes, after an input object lifts from a surface oftouch sensor 150, after a time out, etc.). As further examples, rules ofthis type may cause control circuitry 112 to report in response toselection commands (e.g., button actuation, particular types of userinput in the sensing region of touch sensor 150 such as double touches,etc.). In some embodiments, control circuitry 112 report to hostprocessing system 160 information about the input sequence (e.g.,characters entered, words recognized), images of the input sequence(e.g., strokes detected), locations of touches in the input sequence,gestures sensed or recognized during the input sequence, etc.

Report Application Specific Commands: Rules of this type cause controlcircuitry 112 to return user input specific to particular applications.For example, rules of this type may cause control circuitry 112 toreport user input information associated with changing a radio button ora slider control on a web page.

Embodiments of the present invention performing method 400 can providelow-latency visual feedback to the user that improves user experiencewith electronic device 100. The low-latency visual feedback to the useris facilitated by control circuitry 112 autonomously updating displayscreen 140 in response to user input. Additionally, power consumption byelectronic device 100 is reduced and/or performance requirements ofvarious components of electronic device 100 are relaxed.

Additionally, some rule sets are configured such that TSCS 110 (e.g.,using control circuitry 112 to communicate to host processing system 160information about user input that triggers one or more of the followingevents: (1) switching to a new application, (2) enabling furtherfunctions of a current application, (3) updating a memory of electronicdevice 100 outside of TSCS 110, such as a memory of host processingsystem 160, and (4) triggering telephone calls or internet access.

In various embodiments, some sets of rules (e.g., a first or second setof rules) is configured to cause control circuitry 112 to (1)autonomously update display screen 140 in response to a first type ofuser input (but not in response to a second type of user input) and (2)report user input information in response to the second type of userinput (and not in response to the first type of user input) to hostprocessing system 160. For example, in some embodiments, a first set ofrules causes control circuitry 112 to autonomously update display screen140 in response to a drag gesture, but not in response to a double tapgesture. As another example, in some embodiments, a first set of rulescauses control circuitry 112 to report information about a dragoperation at a termination of the drag operation, but not to reportinformation about the drag operation during the drag operation.

Various ways of autonomously updating display screen 140 that do notinvolve real-time intervention by host processing system 160 exist. Forexample, some embodiments directly adjust the image stored in the framebuffer (perhaps after copying the image in the frame buffer to anotherlocation). As another example, some embodiments use an image blendingapproach to generate and update images on display screen 140. As aspecific example, various embodiments in accordance with the presentinvention use alpha blending technology. Alpha blending is one processfor combining one or more overlay image(s) with a main image, and isuseful for blending image elements from separate sources to create asingle composite image. The overlay and main images may differ in size,resolution, color-depth, aspect ratio, and the like.

In some embodiments, the transparency or blend factor of the overlayimage may be controlled as a percentage that defines the merging of themain image and the overlay image in the overlap region of the twoimages. Outside the overlap region, the main image is displayed withoutany modification.

In many cases, the main image and the overlay image are rectangular inshape. In such embodiments, it is still possible to overlay anon-rectangular shaped image using chroma-key technology. Chroma-keyallows the system to identify a particular color in the overlay image tobe “transparent”. When pixels in the overlay image contain thechroma-key value, the parts of the main image overlapped by these pixelsare displayed unaltered. Thus, various embodiments may hold an overlayimage as a secondary image, hold a background image as a primary image,and use alpha blending to overlay the secondary image onto the primaryimage.

Embodiments utilizing alpha blending or other blending technology maydraw from a variety of blending options. For example, control circuitry112 may blend a secondary image at different locations to generatemultiple, different blended images. The different locations may be withrespect to a primary image, the active area of display screen 140, orboth. This may be done over time, such as to produce a set of blendedimages that move the secondary image when shown in sequence. As anotherexample, control circuitry 112 may blend multiple instances of asecondary image at different locations into one blended image. As yetanother example, control circuitry 112 may blend multiple instances of asecondary image at different locations into multiple blended images,such as to produce a set of blended images that effectively move theinstances of the secondary image.

Embodiments may blend one or more other images in addition to thesecondary image. For example, some embodiments may also blend a tertiaryimage or instances with the tertiary image to form a blended image.

In some embodiments, the primary image is received from host processingsystem 160 and held in TSCS 110 (e.g. in first memory 131 of FIG. 3).One or more images that may be blended with the primary image can beheld in TSCS 110 (e.g. in second memory 132 of FIG. 3). The primaryimage may be static or may change over a period of time. In someembodiments, the primary image is modified, or replaced entirely by hostprocessing system 160, by TSCS 110 (e.g., using control circuitry 112),or by both.

In some embodiments, an image to be blended with the primary image issmaller than the primary image in physical size, bit size, or the like.

In one embodiment, the secondary image is provided by host processingsystem 160. In another embodiment, the secondary image is provided byTSCS 110. The secondary image may be modified by host processing system160, TSCS 110 (e.g., using control circuitry 112), or both. Theprovision or the adaptation of the secondary image may be in response touser input (e.g., user input detected using touch sensor 150).

In some embodiments, the location at which the secondary (or tertiary orother) image is blended is based on the user input. For example, inresponse to user input provided by an input object, a secondary imagemay be blended at a location based on the position of the input object.Specifically, the location may be selected to place the secondary imagesuch that it is overlapped by the input object or offset from the inputobject. The offset may be static or dynamically determined based on userinput factors such as speed, force, duration, and the like. As anotherexample, in response to user in[put provided by multiple input objects,multiple instances of the secondary image (or the secondary image, atertiary image, and optionally other images) may be blended at locationsbased on the positions of the input objects.

In some embodiments, the image(s) selected for blending is based on theuser input. For example, a particular image may be associated with atype of user input sequence, and that particular image may be the imageblended in response to that type of user input sequence. As anotherexample, a particular image may be associated with a type of inputobject, and that particular image may be the secondary image in responseto user input comprising that type of input object.

Some embodiments accomplish blending by regularly or continuouslyupdating coordinates that specify the location(s) where instance(s) of asecondary image is blended. This approach allows TSCS 110 (e.g., usingcontrol circuitry 112) to generate different blended images whileallowing the secondary image to remain unchanged in memory.

Embodiments may also change the blend factor over space, over time, orboth. For example, some embodiments may increase or decrease the blendfactor to fade in or fade out an image. As another example, someembodiments may define different blend factors for different regions ofa primary image or display screen active area. When a secondary image isblended in those regions, the associated blend factors are used.

Blended images may also be used to provide pop-ups that enhance userexperience. For example, during audio, picture, or video playback, mediacontrols (such as play, pause, fast forward, rewind, volume, back,forward, etc) can pop-up over the imagery displayed. This pop-upfunctionality may be used for other controls, such as to drawingcontrols when a drawing program is active, to editing commands when adocument editor is active, and the like.

In reference to FIG. 1, this pop-up response may be provided by TSCS 110(e.g., using control circuitry 112) in response to detection of contact(e.g., taps, touches of particular durations) or non-contact (e.g.,stationary or dynamic hover) user input near display screen 140, withoutinvolvement of host processing system 160. Thus, some embodimentsrespond to select non-contact user input with pop-up menus or controls.Such “floating” or “hover-based”tracking feedback in response to userinput that is not touching the touch sensor 150 may also be implementedusing a blending scheme. In some embodiments, host processing system 160may become involved when the user interacts with one of the controlsshown in the blended image that affects the media displayed.

In various embodiments, the blended image may also be used to providevisual feedback through various icons or other similar images producedresponsive to the user input. For example, if a gesture is performedwhich involves rotating an image, a “rotate” icon can be used as thesecondary image and displayed with the primary image without the hostprocessing system's intervention. Meanwhile, host processing system 160may perform the image processing needed to rotate the image provideupdated primary images as needed to perform the rotation.

With reference now to FIG. 3, some embodiments update display screen 140autonomously in response to user input (e.g., to the drag operationdescribed below) using an embodiment of TSCS that includes first memory131 and second memory 132, and an embodiment of DCC 120 that includesdisplay refresh circuitry 134, which further includes blended imagegenerator 138 and display screen updater 136. The blended imagegenerator 138 autonomously generates blended images by blending aprimary image held in first memory 131 with a secondary image held insecondary memory 132. The display screen updater 136 autonomouslyupdates display screen 140 with the blended images generated by blendedimage generator 138.

Described below, in reference to FIGS. 1-2 and 5A-7B, are specificexamples of operation of specific embodiments of the present invention.FIGS. 5A-7B depict visual feedback on display screen 140 in response touser input detected using touch sensor 150, in accordance to embodimentsof the present invention. In various examples, operation of variousembodiments the present invention includes operating according to setsof rules that define when control circuitry 112 (1) autonomously updatesdisplay screen 140 in response to user input and/or (2) reportsinformation about the user input to host processing system 160.

Referring now to FIG. 5A, a drag operation is depicted, in accordance toan embodiment of the present invention. In general, in response to userinput, an image 520A is animated as being dragged along user input path530A from location 510A to location 514A.

Before the drag operation, control circuitry 112 operates according to afirst set of rules. In response to an initiation of the drag operationat location 510A, control circuitry 112 switches from operatingaccording to a first set of rules to operating according to a second setof rules. In some embodiments, control circuitry 112 providesinformation about the user input that enables host processing system 116to determine that a drag operation has begun, and provides an indicationto control circuitry 112 to switch to operating according to the secondset of rules. In some embodiments, control circuitry 112 recognizes thata drag operation has begun, notifies host processing system 116 that thedrag operation has begun, and host processing system 116 provides anindication to control circuitry 112 to switch to operating according tothe second set of rules.

In this example, the second set of rules defines when control circuitry112 updates display screen in response to the user input and whencontrol circuitry 112 reports information about the user input to hostprocessing system 160. For example, when operating in accordance withthis second set of rules, information about the initiation of a dragoperation of image 520A at location 510A (e.g., first type of userinput) is reported to host processing system 160 by control circuitry112 in response to user input that initiates the drag operation.However, information about subsequent drag action (e.g., at least someof the object motion “dragging” image 520A along user input path 530A)is not reported to host processing system 160 in response to thesubsequent drag action.

In various embodiments, a set of rules is configured to cause controlcircuitry 112 to update display screen 140 in response to a first typeof user input and not in response to a second type of user input. Forexample, a particular set of rules may define that, in response to aparticular type of user input, that control circuitry 112 autonomouslyupdates display screen 140 in response to that particular type of userinput. This particular set of rules may further contain specific rulesfor not autonomously updating display screen 140 in response to anothertype of user input, or further lack any rules about updating displayscreen 140 in response to such user input.

Returning now to FIG. 5A and the example discussed above, the second setof rules associated with this example is configured to cause controlcircuitry 112 to update display screen 140 in response to parts of thedrag sequence. For example, as image 520A is dragged along user inputpath 530A, display screen 140 is autonomously updated with image 520A atdifferent locations along user input path 530A. Accordingly, image 520Ais animated by control circuitry 112 as being dragged along user inputpath 530A from location 510A to location 514A. As a result ofautonomously updating display screen 140, visual feedback latency inresponse to user input may be reduced.

The following is an example of the drag operation, as described above,with further details relating to the autonomous updating of displayscreen 140. The example described below utilizes blending technology.Specifically, control circuitry 112 blends of primary image 505A (e.g.,a background image) and image 520A (shown as a circular icon) to produceblended images that are used to update display screen 140.

In FIG. 5A, a user input sequence for a drag operation is provided. Theinput sequence comprises a drag initiation gesture located at location510A. In response to the drag initiation gesture, host processing system160 provides an indication to TSCS 110 to operate according to thesecond set of rules. While operating according to the second set ofrules, blended images comprising primary image 505A and image 520A areautonomously generated by control circuitry 112. Furthermore, displayscreen 140 is autonomously updated by control circuitry 112 with theblended images.

As user input path 530A is traced out by the one or more input objectsproviding the user input sequence, multiple blended images areautonomously generated by control circuitry 112. These blended imagesdepict image 520A at different locations along (or offset from) userinput path 530A. Display screen 140 is autonomously updated by controlcircuitry 112 with these blended images. For example, when the one ormore input objects providing the user input are positioned at location512A along user input path 530A, a blended image is autonomouslygenerated by control circuitry 112. This blended image locates thesecondary image 520A in a position determined by the user input atlocation 512A, and in front of the primary image 505A. Display screen140 is autonomously updated with this blended image by control circuitry112.

Similarly, when the one or more input objects providing the user inputsequence is located at location 514A, a blended image is autonomouslygenerated by control circuitry 112 in response to the user input anddisplay screen 140 is autonomously updated with the blended image bycontrol circuitry 112. This blended image locates image 520A in aposition determined by the user input at location 514A. In response tomovement of the user input, control circuitry 112 repeatedly updates thelocations at which image 520A is blended. Control circuitry 112 alsorepeatedly updates the display screen 140 with the blended images. Thismoves the secondary image 520A (with respect to primary image 505A,display screen 140, or both).

FIG. 5A depicts the same image 520A being blended with primary image505A at different parts of the drag function, in accordance to anembodiment of the second set of rules. Other embodiments operatingaccording to other sets of rules may blend different images at differentpoints in time, space, or user input function sequence, in accordance toother sets of rules. For example, in some embodiments, an imageindicative of drag initiation may be blended with primary image 505Anear location 510A, an image indicative of drag continuation may beblended with primary image 505A at location 512A, or an image indicativeof drag termination may be blended with primary image 505A at location514A.

In some embodiments, primary image 505A changes or is replaced duringthe drag function.

In some embodiments, in response to a termination of the drag operation,host processing system 160 updates the primary image held in TSCS toinclude the item that was dragged at a new location determined by thedrag operation. For example, after the drag operation shown in FIG. 5Aterminates at location 514A, some embodiments update the primary image505A to include an image of the item dragged (the circular icon that wasthe secondary image 520A) at the new location 514A. In some embodiments,host processing system 160 performs this updating of the primary image.

With such an approach, the primary image 505A as stored in memory is notcorrupted or changed while the blended images depict secondary image520A being dragged in response to user input.

The secondary image 520A shown is the item that the user is dragging.However, in some embodiments, in accordance to various sets of rules,different images are considered the secondary image and blended fordifferent operations. For example, a blue star may be provided when adrag operation occurs. In contrast, two stacked fingers may be providedin response to another operation, such as a double-tap operation.

In an analogous example, in some embodiments, control circuitry 112operates touch sensor 150 to detect user input (e.g., comprising afinger hovering over or touching display screen 140 and moving acrossdisplay screen 140). Control circuitry 112, autonomously updates displayscreen 140 to provide visual feedback (e.g., a moving cursor, ahistorical trace, etc.) without requiring intervention by the associatedhost processing system 160. In some embodiments, host processing system160 intervenes when the user interacts with an icon or other interactiveelement shown on display screen 140.

In one embodiment of method 400, autonomously updating display screen140 when displaying a first portion of an image on display screen 140comprises detecting a motion of a first user input in the sensingregion, determining a second portion of the image to be displayed basedon the motion, and updating display screen 140 to display the secondportion of the image. A second set of rules can be configured to causecontrol circuitry 112 to perform these steps.

For example, referring now to FIG. 5B, a pan operation performed by twoinput objects (e.g. a two-finger pan operation) is depicted, inaccordance to an embodiment of the present invention. In someembodiments, the primary image 505B shown in display screen 140 is aportion of a larger image (e.g., a map, a picture, a text document, aweb page). The pan operation depicted in FIG. 5B changes what is shownby display screen 140 to simulate moving a “viewport” over the largerimage. In some embodiments, host processing system 160 updates theprimary image to provide the simulated motion. In some otherembodiments, TSCS holds the larger image in memory, and TSCS 110 (e.g.,using control circuitry 112) determines what portion of the larger imageto display. For clarity, the changing image is not shown FIG. 5B.

As described above, some embodiments of TSCS 110 may implement viewportsautonomously. In some implementations of viewports, TSCS 110 isconfigured to hold more image data than can be displayed at one time bybeing physically larger, via compression of image data, or a combinationthereof. The compression technology could be highly efficient (e.g.,Run-length encoding (RLE)-based compression) or could be lossy (e.g.,individual pixel replacement). In some embodiments, during operation,the “viewport” may be the same size or smaller than the physical size ofthe active area of display screen 140. The “viewport” can be virtuallymoved over the image, such as in response to user input in the sensingregion, and define what image data is displayed on display screen 140.

The following is an example of the pan operation that simulates moving a“viewport”, as described above, with further details relating to theblending of primary image 505B and secondary image 520B. Initially,control circuitry 112 operates according to a first set of rules. Inresponse to receiving an indication from host processing system 160,control circuitry 112 switches from operating from a first set of rulesto the second set of rules.

As shown in FIG. 5B, to indicate the panning function, secondary image520B and tertiary image 525B are blended with primary image 505B atlocations associated with first and second input objects. As shown,secondary image 520B is associated with a first input object followinguser input path 530B and tertiary image 525B is associated with a secondinput object following user input path 435B. Accordingly, theautonomously generated blended image comprises primary image 505B,secondary image 520B and tertiary image 525B. As the input objects move,control circuitry 112 repeatedly generates blended images with thesecondary image 520B and tertiary image 525B at locations associatedwith positions of the input objects, and repeatedly updates displayscreen 140 with the blended images. Thus, secondary image 520B andtertiary image 525B move in such a way that they appear to follow theinput objects along user input paths 530B an 535B.

Referring to FIG. 5C, another two-input-object panning operation isdepicted, in accordance to an embodiment of the present invention. Theoperation depicted in FIG. 5C is similar to the operation depicted inFIG. 5B, as described above. However, to indicate the function, asecondary image is blended at two different locations with respect tothe primary image. For convenience, they are referred to here assecondary image 520C and copy of secondary image 525C. Secondary image520C is associated with a first input object following user input path530C. Similarly, copy of secondary image 525C is associated with asecond input object following user input path 535C. Accordingly, theautonomously generated blended image comprises primary image 505C,secondary image 520C and copy of secondary image 525C. As the inputobjects move, control circuitry 112 repeatedly generates blended imageswith secondary image 520C and copy of secondary image 525C at differentlocations with respect to display screen 140 (or another appropriatereference, such as with respect to primary image 505C), and repeatedlyupdates display screen 140 with the blended images. Thus, secondaryimage 520C and copy of secondary image 525C appear to move with respectto the primary image 505C and/or display screen 140, and follow theinput objects along user input paths 530C and 535C, respectively.

As a specific example, a secondary image may comprise an angle shape. Inresponse to a “pinch” or “spread” user input with input objects movingtogether or moving apart, respectively, the angle shape may be orientedand located to follow the input object motion. In some embodiments, thiscan emulate two or more corners of a picture frame, and the expanding orcontracting of that picture “frame”.

In some embodiments, in accordance to a set of rules, the secondaryimage is blended to highlight portion(s) of the primary image. In someembodiments, the secondary image is blended at location(s) correspondingto position of user input.

An end to a sequence of user input operations is determined, forexample, when the user input comprises one or more input objects liftingaway from a surface of the touch sensor 150 or exiting the sensingregion. Some embodiments determine the end by determining that userinput is no longer sensed in the sensing region of touch sensor 150. Insome embodiments, TSCS (e.g., using control circuitry 112) provides anindication of the sequence of user input operations to host processingsystem 160 in response to the termination of the sequence of user inputoperations. The indication provided to host processing system 160 maycomprise a signal purely indicating the termination, may compriseinformation about the user input (e.g. gestures recognized, charactersinputted, overall motion of input objects comprising the user input,functions selected text entered, etc.), a combination thereof, and thelike. In some embodiments, the indication may cause host processingsystem 160 to switch from a low power state to a full power state,launch or close an application, etc.

In a further embodiment of method 400, control circuitry 112 operatesaccording to a second set of rules when display screen 140 displays avirtual keyboard. An image associated with the virtual keyboard isautonomously updated in response to the user input. In one embodiment,the second set of rules comprises sometimes reporting information aboutuser manipulation of the virtual keyboard to host processing system 160.

For example, in reference to FIGS. 6A-B, primary image 605A comprises animage of a virtual keyboard. The primary image 605A may be stored inTSCS 110 (e.g. in first memory 131 of FIG. 3). A plurality of key images(e.g., an actuated image of the space bar key image 620A) associatedwith the virtual keyboard may be stored in TSCS 110 (e.g. in secondmemory 132 of FIG. 3). User actuation of a key (e.g., space key) of thevirtual keyboard based on the user input is determined by TSCS 110(e.g., using control circuitry 112). An image of the plurality of keyimages is selected as the image to be blended with the primary image,such that the blended image shows the virtual keyboard with actuation ofthe selected key.

In particular, as shown in FIGS. 6A-B, user input is provided foractuation of space bar 620A on the virtual keyboard. In response to userinput for actuation of space bar 620A, a secondary image 620B of FIG. 6Bof an actuated space bar is selected and blended to show the space baractuated on the virtual keyboard.

In another embodiment of method 400, TSCS 110 blends multiple imageswith the primary image to generate the blended image. For example, theprimary image may comprise an image of a virtual keyboard and thesecondary image may comprise a generic key image. In response to userinput actuating a key of the virtual keyboard (e.g., “#”), TSCS 110blends an appropriate, additional image associated the “#” key with theprimary and secondary images, such that the blended image shows thevirtual keyboard with actuation of the selected key.

In some embodiments, a secondary image may be modified in response touser input by TSCS 110 (e.g., using control circuitry 112), withoutintervention by host processing system 160. As some examples, themodification may affect the secondary image's size, shape, color,transparency, etc. For example, the primary image may comprise an imageof a virtual keyboard and the secondary image may comprise a generic keyimage. In response to user input actuating a key of the virtual keyboard(e.g., “W”), TSCS 110 modifies the secondary image to place a “W” in anappropriate part of the secondary image, such that the blended imageshows the virtual keyboard with actuation of the selected key.

Indicators other than images of actuated keys may be used to providevisual feedback from key actuation. For example, referring to FIGS.6A-B, a highlighter comprising a colored rectangle may be the secondaryimage 620B blended with the primary image 620A to provide visualfeedback of actuation. In some embodiments the same highlighter(modified or not modified by TSCS 110) is used for multiple keys.

Highlighting of keys may be used to indicate which key(s) would beactuated if a selection input was provided, instead or in addition toindicating key actuation (s). For example, non-contact user input thathovers over an area associated with the “Q” key for more than areference amount of time may cause the “Q” key to highlight. Contactuser input may then cause actuation of the “Q” key and entry of “Q” intoa memory buffer.

In one embodiment of method 400, in reference to FIGS. 7A-B, controlcircuitry 112 operates according to a second set of rules. The secondset of rules comprises autonomously updating display screen 140 todisplay a trace of a movement of the user input, in response to themovement. For example, TSCS 110 modifies secondary image 720A such thatit comprises inking associated with movement of the user input.

In particular, a user input of a handwritten letter “T” is provided inFIGS. 7A-B. As the handwritten letter “T” is created by the user inputalong user input paths 721 and 722, TSCS 110 (e.g., using controlcircuitry 112) in accordance to the second set of rules, modifies thesecondary image to match. Thus, the blended images that are autonomouslygenerated and used to update display screen 140 inks along thehandwritten letter “T”. That is, the repeated blending of primary image705A and the adapted secondary image 720A shows inking. Furthermore, insome embodiments, when the user's input of the handwritten letter “T” isrecognized as the letter “T,” the handwritten letter “T” is replacedwith a typed letter “T” on display screen 140.

In various embodiments, host processing system 160 of FIG. 1 downloadscharacter recognition code into TSCS 110. TSCS 110 (e.g., using controlcircuitry 112) implements most or the entire character recognitionfunctionality. This can include low-latency stroke drawing, hapticfeedback, and dictionary correction, and the like. A standardhandwriting or keypad input interface can be used for communicating withhost processing system 160. Host processing system 160 can configurecharacter recognition functionality by downloading different code, fordifferent languages, character sets, etc.

In another embodiment of method 400, TSCS 110 (e.g., using controlcircuitry 112) provides indication to host processing system 160 thattriggers host processing system 160 to be in a low power state during.In various embodiments, the indication comprises user input information,from which host processing system 160 determines that it may enter a lowpower state. In some embodiments, the indication comprises a signalspecifically to indicate to host processing system 160 that it may entera low power state. In another embodiment, the indication occurs duringat least part of the generating an image (e.g. a blended image) andupdating display screen 140 with the image.

For example, in some embodiments, a set of rules may provide that TSCStrigger host processing system 160 to be in a low power state once it isdetermined that the drag operation has initiated.

In another embodiment, host processing system 160 provides software andrules to implement a complete nested menu GUI to TSCS 110. The user cannavigate through the nested menu structure without any intervention fromhost processing system 160. TSCS 110 (e.g., using control circuitry 112)renders the menus and host processing system 160 can go into a lowerpower state. When the user makes a menu selection, the processing system160 is awakened if necessary and the processing responsibility istransferred back to processing system 160 as appropriate.

In various embodiments, host processing system 160 is configured forproviding the indication that is configured to cause control circuitry112 to switch to operating according to a second set of rules inresponse to a first application running on host processing system 160.In some embodiments, host processing system 160 is further configuredfor providing a second indication in response to a second applicationrunning on host processing system 160. The second indication isconfigured to cause control circuitry 112 to switch to operatingaccording to the first set of rules.

For example, in some embodiments, when a word processing application isrunning on host processing system 160, host processing system 160provides an indication to cause control circuitry 112 to switch tooperating according to a second set of rules. Similarly, when a webbrowser is running on host processing system 160, host processing system160 provides an indication to cause control circuitry 112 to switch tooperating according to a first set of rules.

In some embodiments, host processing system 160 is configured forproviding the indication in response to a first application running onhost processing system 160 and having priority over any otherapplication running on said host processing system 160, and providing asecond indication in response to a second application running on hostprocessing system 160 and having priority over any other applicationrunning on host processing system 160. The indication is configured tocause control circuitry 112 to switch to operating according to a secondset of rules. The second indication is configured to cause controlcircuitry 112 to switch to operating according to the first set ofrules.

For example, in some embodiments where a word processing application anda web browser are both running on host processing system 160, the wordprocessing application may have the focus sometimes, and the web browsermay have the focus sometimes. The web browser has focus or priority overthe word processing application when the user is actively using the webbrowser. Similarly, the word processing application has focus orpriority over the web browser when the user is actively using the wordprocessing application.

If the word processing application has focus or priority over the webbrowser (or any other application running on host processing system160), then host processing system 160 provides a first indication. Ifthe web browser subsequently has focus or priority over the wordprocessor (or any other application running on host processing system160), then host processing system 160 provides a second indication. Thefirst indication is configured for causing control circuitry 112 toswitch to operating according to a second set of rules specific to theword processing application. The second indication causing controlcircuitry 112 to switch to operating according to a first set of rulesspecific to the web browser. The word processing and web browser areexample applications, and any number and type of applications may run onhost processing system 160

Moreover, TSCS 110 may provide an interpretation of the user input aspart of its communication with the host processor when operatingaccording to some sets of rules. The interpretive function of TSCS 110can be made reconfigurable or application specific. In some embodiments,TSCS 110 (e.g. using control circuitry 112) does not report everyinstance of user input to host processing system 160, but rather onlythose instances of user input that are significant or relevant to theapplication being processed at a given time.

In some embodiments, host processing system 160 is configured forproviding the indication when a first image is displayed on displayscreen 140, and for providing a second indication when a second image isdisplayed on display screen 140. The indication is configured forcausing control circuitry 112 to switch to operating according to asecond set of rules specific to the first image. The second indicationis configured to cause control circuitry 112 to switch to operatingaccording to a first set of rules specific to the second image.

For example, in some embodiments of FIG. 5A, if primary image 505A is animage of a software application, then host processing system 160provides an indication such that control circuitry 112 operatesaccording to a set of rules (e.g., a second set of rules). If primaryimage 505A is an image of a dialog box (e.g., a search dialog) of thatsoftware application, then host processing system 160 provides anindication such that control circuitry 112 operates according to anotherset of rules (e.g., a first set of rules).

In various embodiments of the present invention, various devices otherthan display screen 140 provide feedback to the user. In one embodiment,a haptic actuator (not shown) is controlled by device control module 125(show in FIG. 3) and provides haptic feedback to the user, in accordanceto a set of rules. As a result of the haptic feedback, a user's sense ofcomfort and confidence in electrical device 100 of FIG. 1 is enhanced.In one example, the haptic actuator provides tactile feedback such as aphysical resistance or a non-linear mechanical response to user input.In another example, the haptic actuator provides a buzzing or avibratory response to user input. Other devices may be utilized thatprovide aural feedback via clicks, pings, thuds, or other sounds.

Moreover, alternate or additional components, such as other interface orfeedback devices may be utilized. These alternate or additional devicesinclude microphones, speakers and other audio devices, force sensors,motion sensors, accelerometers, gyroscopes, optical detectors, imagingdevices, mechanical buttons, latches, levers, sliders and the like.

In various embodiments of the present invention, electronic device 100includes a security function without requiring intervention by hostprocessing system 160, in accordance to a set of rules. In oneembodiment, electronic device 100 is unlocked, in response to sensinguser input in a sensing region overlapping an active area of saiddisplay screen 140. TSCS 110 may not allow host processing system 160 topower up or allow electronic device 100 to accept other input untilelectronic device 100 is unlocked.

In another embodiment, in response to a failed attempt to unlockelectronic device 100, a secondary image configured for responding to afailed attempt to unlock electronic device 100 is displayed on displayscreen 140.

In various embodiments, TSCS 110 holds secure passwords and encryptionkeys in a protected area of its memory that cannot be read out by hostprocessing system 160. In accordance to a set of rules, TSCS 110 (e.g.,using control circuitry 112) displays an on-screen, virtual keypad thatallows users to enter passwords. TSCS 110 then compares user input viathe keypad to one or more passwords held in memory. If the password iscorrect, TSCS 110 releases an encryption key to host processing system160. Because host processing system 160 is not involved in the holdingor entry of the password, malicious software running on host processingsystem 160 cannot snoop on the holding and/or entry of the password.

Various embodiments of the present invention are thus described. Whilethe present invention has been described in particular embodiments, itshould be appreciated that the present invention should not be construedas limited by such embodiments, but rather construed according to thefollowing claims.

What is claimed is:
 1. A touch screen control system configured tocommunicate with a host processing system, said touch screen controlsystem comprising: a memory; and control circuitry configured to operatea touch screen comprising a touch sensor and a display screen accordingto rules stored in said memory by: during a first time period and inresponse to detecting a first type of user input with said touch sensor,updating said display screen autonomously and without requiringintervention from said host processing system following said detectionof said first type of user input; during said first time period and inresponse to detecting a second type of user input with said touchsensor, updating said display screen according to directions provided bysaid host processing system; and during a second time period and inresponse to detecting said first type of user input with said touchsensor, updating said display screen according to directions provided bysaid host processing system.
 2. The touch screen control system of claim1, wherein said control circuitry is further configured to: during saidsecond time period and in response to detecting said second type of userinput with said touch sensor, updating said display screen according todirections provided by said host processing system.
 3. The touch screencontrol system of claim 1, wherein said touch screen control systemcomprises: display control circuitry for updating said display screen;and touch sensor control circuitry for operating said touch sensor andconfigured for direct communications with said display controlcircuitry.
 4. The touch screen control system of claim 3, wherein saiddisplay control circuitry and said touch sensor control circuitry shareprocessing circuitry.
 5. The touch screen control system of claim 3,wherein said display control circuitry and said touch sensor controlcircuitry form a same IC.
 6. The touch screen control system of claim 3,wherein said display control circuitry and said touch sensor controlcircuitry comprise separate ICs.
 7. The touch screen control system ofclaim 1, wherein said control circuitry is further configured to duringsaid first time period, not report a selected part of an input sequenceeven as said control circuitry autonomously updates said display screenin response to said selected part of said input sequence.
 8. The touchscreen control system of claim 7, wherein said control circuitry isconfigured to not report a selected part of said input sequence even assaid control circuitry autonomously updates said display screen inresponse to said selected part of said input sequence by: not reportingan intervening part of said input sequence even as said controlcircuitry autonomously updates said display screen in response to saidintervening part of said input sequence, said intervening part of saidinput sequence being between an initiation and a termination of saidinput sequence.
 9. The touch screen control system of claim 7, whereinsaid control circuitry is further configured to provide an indication tosaid host processing system to enter a low power state in response todetecting an initiation of said input sequence.
 10. The touch screencontrol system of claim 7, wherein said control circuitry is furtherconfigured to provide an indication to said host processing system toenter a full power state in response to detecting a termination of saidinput sequence.
 11. The touch screen control system of claim 1, whereinsaid first type of user input is a drag operation, and wherein saidcontrol circuitry is further configured to: in response to an initiationof said drag operation, initiate said first time period.
 12. The touchscreen control system of claim 11, wherein said control circuitry isfurther configured to: in response to a termination of said dragoperation, end said first time period.
 13. The touch screen controlsystem of claim 11, wherein said control circuitry is further configuredto during said first time period, not report an intervening part of saiddrag operation even as said control circuitry autonomously updates saiddisplay screen in response to said intervening part of said dragoperation, said intervening part of said drag operation being between aninitiation and a termination of said drag operation.
 14. A method ofoperating a touch screen control system for an electronic devicecomprising a touch sensor and a display screen overlapped with a sensingregion of said touch sensor, said method comprising: during a first timeperiod and in response to detecting a first type of user input with saidtouch sensor, updating said display screen autonomously and withoutrequiring intervention from a host processing system following saiddetection of said first type of user input; during said first timeperiod and in response to detecting a second type of user input withsaid touch sensor, updating said display screen according to directionsprovided by a host processing system; and during a second time periodand in response to detecting said first type of user input with saidtouch sensor, updating said display screen according to directionsprovided by said host processing system.
 15. The method of claim 14,wherein said first type of user input comprises an input sequence, themethod further comprising: during said first time period, not reportingan intervening part of said input sequence even as said display screenis autonomously updated in response to said intervening part of saidinput sequence, said intervening part of said input sequence beingbetween an initiation and a termination of said input sequence.
 16. Themethod of claim 14, further comprising: providing an indication to saidhost processing system to enter a low power state before said first timeperiod.
 17. The method of claim 14, further comprising: providing anindication to said host processing system to enter a full power stateafter said first time period.
 18. The method of claim 14, wherein saidfirst type of user input is a drag operation, further comprising: inresponse to an initiation of said drag operation, initiating said firsttime period; and in response to a termination of said drag operation,terminating said first time period.
 19. A handheld computing devicecomprising: a touch screen comprising a touch sensor and a displayscreen; a host processing system; and a touch screen control systemconfigured to communicate with said host processing system, said touchscreen control system comprising: a memory; and control circuitryconfigured to operate said touch screen according to rules stored insaid memory by: during a first time period and in response to detectinga first type of user input with said touch sensor, updating said displayscreen autonomously and without requiring intervention from said hostprocessing system following said detection of said first type of userinput; during said first time period and in response to detecting asecond type of user input with said touch sensor, updating said displayscreen according to directions provided by said host processing system;and during a second time period and in response to detecting said firsttype of user input with said touch sensor, updating said display screenaccording to directions provided by said host processing system.
 20. Thehandheld computing device of claim 19, wherein said control circuitry isfurther configured for: during said second time period and in responseto detecting said second type of user input with said touch sensor,updating said display screen according to directions provided by saidhost processing system.